Research Status and Hotspots of Quantum Computing

doi:10.3778/j.issn.1002-8331.2303-0487

Abstract

Abstract: Exploring the international research status, hotspots and future development trend of quantum computing is significant for China’s strategic deployment and technological planning. The literature related to quantum computing collected in the Web of Science database from 2007 to 2021 is taken as the research object. Based on bibliometric and content analysis methods, text mining and visualization analysis tools are used to explore the research status in this field from the dimensions of publication trend, major countries, institutions, researchers, hotspots, and development trends. Studies have shown that： quantum computing literature presents an increasing trend year by year; the United States ranks first in literature number and citations per article, and has strong scientific research strength; China has a group of influential institutions and scholars in this field, but the cooperation intensity between institutions is low; research hotspots are distributed in quantum algorithms, quantum computing models, the physical realization of quantum computers and the application of quantum computing; research frontiers focus on quantum computing model and the application in artificial intelligence, cryptanalysis and other fields.

Key words: quantum computing, bibliometrics, content analysis, knowledge mapping, research hotspot

摘要： 探究量子计算领域国际研究态势、研究热点和发展趋势对我国在该领域的战略部署和科技规划具有重要的借鉴和参考意义。以Web of Science数据库2007—2021年收录的量子计算领域的文献作为研究对象，基于文献计量和内容分析的方法，利用文本挖掘和可视化分析工具从发文趋势、主要国家、研究机构、研究人员、研究热点和发展趋势等维度探究该领域的研究态势。研究发现，量子计算领域发文量总体上呈现逐年递增趋势；美国的发文量和篇均被引频次位居首位，拥有雄厚的科研实力；我国在该领域拥有一批有影响力的研究机构和学者，但是机构间合作强度较低；研究热点主要分布在量子算法、量子计算模型、量子计算机的物理实现以及量子计算的应用等方面；研究前沿主要聚焦在量子计算模型研究以及量子计算在人工智能、密码分析等领域的应用。

关键词: 量子计算, 文献计量, 内容分析, 知识图谱, 研究热点

ZHAO Jian, LYU Fengxian. Research Status and Hotspots of Quantum Computing[J]. Computer Engineering and Applications, 2023, 59(19): 1-9.

赵建, 吕凤先. 量子计算研究态势及热点分析[J]. 计算机工程与应用, 2023, 59(19): 1-9.

References

[1] 王立娜，唐川，田倩飞，等.全球量子计算发展态势分析[J].世界科技研究与发展，2019，41（6）：569-584.
WANG L N，TANG C，TIAN Q F，et al.Analysis on the development strategies and trends of global quantum computing[J].World Science and Technology Research and Development，2019，41（6）：569-584.
[2] 孔月，李秀霞.基于引文邻近位置的作者共被引分析[J].信息资源管理学报，2019，9（4）：37-44.
KONG Y，LI X X.The authors co-citation analysis based on references proximity position[J].Journal of Information Resources Management，2019，9（4）：37-44.
[3] 邱均平，赵蓉英，董克，等.科学计量学[M].北京：科学出版社，2019：244-245.
QIU J P，ZHAO R Y，DONG K，et al.Scientometrics[M].Beijing：Science Press，2019：244-245.
[4] NIELSEN M A，CHUANG I L.Quantum computation and quantum information[M].Cambridge：Cambridge University Press，2000.
[5] FEYNMAN R.Simulating physics with computers[J].International Journal of Theoretical Physics，1982，21（6）：467-488.
[6] KITAEV A Y.Fault-tolerant quantum computation by anyons[J].Annals of Physics，2003，303：2-30.
[7] RAUSSENDORF R，BRIEGEL H J.A one-way quantum computer[J].Physical Review Letters，2001，86：5188-5191.
[8] SHOR P W.Polynomial-time algorithms for prime factorization and discrete logarithms on a quantum computer[J].SIAM Journal on Computing，1997，26（5）：1484-1509.
[9] GROVER L K.A fast quantum mechanical algorithm for database search[C]//Proceedings of the 28th Annual ACM Symposium on Theory of Computing，1996：212-219.
[10] GROVER L K.Quantum mechanics helps in searching for a needle in a haystack[J].Physical Review Letters，1997，79：325-328.
[11] 赵蓉英，李飞.基于社会网络分析方法的国内外信息计量比较研究[J].情报科学，2013，31（2）：7-12.
ZHAO R Y，LI F.A comparative study of informetrics in China and in foreign countries based on social network analysis[J].Information Science，2013，31（2）：7-12.
[12] DEUTSCH D.Quantum-theory，the church-turing principle and the universal quantum computer[J].Proceedings of the Royal Society A—Mathematical Physical and Engineering Sciences，1985，400：97-117.
[13] DEUTSCH D，JOZSA R.Rapid solution of problems by quantum computation[J].Proceedings of the Royal Society A—Mathematical Physical and Engineering Sciences，1992，439：553-558.
[14] SHOR P W.Algorithms for quantum computation：discrete logarithms and factoring[C]//Proceedings of 35th Annual Symposium on Foundations of Computer Science，1994：124-134.
[15] HARROW A W，HASSIDIM A，LLOYD S.Quantum algorithm for linear systems of equations[J].Physical Review Letters，2009，103：150502.
[16] PERUZZO A，MCCLEAN J，SHADBOLT P，et al.A variational eigenvalue solver on a photonic quantum processor[J].Nature Communications，2014，5：1-7.
[17] FARHI E，GOLDSTONE J，GUTMANN S.A quantum approximate optimization algorithm[J].arXiv：1411.4028，2014.
[18] IBM.IBM unveils breakthrough 127-qubit quantum processor[EB/OL].（2021-11-16）[2022-07-15].https：//newsroom.ibm.com/2021-11-16-IBM-Unveils-Breakthrough-127-Qubit-Quantum-Processor.
[19] ARUTE F，ARYA K，BABBUSH R，et al.Quantum supremacy using a programmable superconducting processor[J].Nature，2019，574：505-510.
[20] GONG M，WANG S Y，ZHA C，et al.Quantum walks on a programmable two-dimensional 62-qubit superconducting processor[J].Science，2021，372：948-952.
[21] CIRAC J I，ZOLLER P.Quantum computations with cold trapped ions[J].Physical Review Letters，1995，7：4091.
[22] ZHONG H S，WANG H，DENG Y H，et al.Quantum computational advantage using photons[J].Science，2020，370：1460-1463.
[23] DEUTSCH D.Quantum computational networks[J].Proceedings of the Royal Society A—Mathematical Physical and Engineering Sciences，1989，425：73-90.
[24] FARHI E，GOLDSTONE J，GUTMANN S，et al.Quantum computation by adiabatic evolution[J].arXiv：quant-ph/0001106，2000.
[25] AHARONOV D，VAN DAM W，KEMPE J，et al.Adiabatic quantum computation is equivalent to standard quantum computation[J].SIAM Journal on Computing，2007，37（1）：166-194.
[26] O’NEILL B，BARLOW T M，SAFRANEK D，et al.Hidden quantum Markov models with one qubit[C]//Proceedings of the International Conference of Numerical Analysis and Applied Mathematics（ICNAAM），2012：667-669.
[27] CONG I，CHOI S，LUKIN M D.Quantum convolutional neural networks[J].Nature Physics，2019，15（12）：1273-1278.
[28] DALLAIRE-DEMERS P L，KILLORAN N.Quantum generative adversarial networks[J].Physical Review A，2018，98：012324.
[29] LI J，LI N，ZHANG Y，et al.A survey on quantum cryptography[J].Chinese Journal of Electronics，2018，27（2）：223-228.
[30] MIYAMOTO K.Bermudan option pricing by quantum amplitude estimation and chebyshev interpolation[J].EPJ Quantum Technology，2022，9（1）：1-27.
[31] RAMOS-CALDERER S，PEREZ-SALINAS A，GARCIA-MARTIN D，et al.Quantum unary approach to option pricing[J].Physical Review A，2021，103：032414.
[32] KHAN A T，CAO X W，LI S，et al.Quantum beetle antennae search：a novel technique for the constrained portfolio optimization problem[J].Science China-Information Sciences，2021，64（5）：152204.
[33] CAO Y，ROMERO J，ASPURU G A.Potential of quantum computing for drug discovery[J].IBM Journal of Research and Development，2018，62（6）：1-20.